An electrowetting display device may comprise pixels that include: a hydrophobic layer portion disposed on a first electrode, electrowetting fluids overlying the hydrophobic layer portion, and a thin film transistor (TFT) that is in electrical contact with the first electrode. The electrowetting display device also comprises a display control circuit in electrical contact with a drain or a source of the TFT of each of the pixels to provide a drive voltage to the drain or the source of the TFT of each of the pixels, and a reset control circuit in electrical contact with the drain or the source of the TFT of each of the pixels to provide a reset voltage pulse to the drain or the source of the TFT of each of the pixels. A magnitude of the reset voltage pulse may be based, at least in part, on the drive voltage.

A liquid lens can include a lens body forming a cavity with a conducting liquid and an insulating liquid disposed therein, the conducting liquid substantially immiscible with the insulating liquid to define an interface between the conducting and insulating liquids. The conducting liquid can include an ionic compound of either a dicyanamide anion and a cation counterion, or a tricyanomethanide anion and a cation counterion, the dicyanamide anion having the formula the tricyanomethanide anion having the formula and the cation counterion is one of an imidazolium, a pyrrolidininium, a piperidinium, a phosphonium, a pyridinium, a pyrrolinium or a sulfonium cation. The ionic compound of the conducting liquid can be N-methyl-N-ethylpyrrolidinium dicyanamide, 1-ethyl-3-methylimidazolium dicyanamide, 1-butyl-1-methylpyrrolidinium tricyanomethanide, or 1-ethyl-3-methylimidazolium tricyanomethanide, among others. The conducting liquid can have transmittance of at least 50% over a thickness of 1 mm for electromagnetic waves having wavelength of 1550 nm. ##STR00001##

A liquid aperture, an electronic device, and a driving method and apparatus for a liquid aperture are provided. The liquid aperture includes a first substrate, a first electrode plate, an insulation layer, a hydrophobic layer, a hydrophilic layer, a sidewall, a second electrode plate, and a second substrate that are disposed adjacent to each other in sequence in a direction of an optical axis of the liquid aperture. A first hollow structure is formed in a middle of the sidewall. The hydrophilic layer includes a first hydrophilic part and a second hydrophilic part. There are N second hollow structures between the first hydrophilic part and the second hydrophilic part. The first hollow structure communicates with the N second hollow structures to form a closed cavity. The closed cavity is filled with a transparent electrolyte and dyed oil. The dyed oil is incompatible with the transparent electrolyte.

An intraocular micro-display (IOMD) implant includes an enclosure shaped for implantation into an eye, a micro-display, a base lens, and an adjustable lens. The micro-display is disposed in the enclosure and oriented to emit an image towards a retina of the eye. The base lens has a fixed optical power, is attached to the enclosure, and is positioned relative to the micro-display to reside in an optical path extending between the micro-display and the retina. The base lens is configured to apply the fixed optical power to the image. The adjustable lens is disposed in the optical path between the micro-display and the retina. The adjustable lens has an adjustable optical power that is adjustable in-situ to adjust a focal distance of the image projected by the IOMD implant after the IOMD implant has been implanted into the eye.

This application is applicable to the field of display technology, and provides a display method, a display apparatus and a computer-readable storage medium, which are applied to a display apparatus, including: acquiring position information of a target content in a pixel electrode array; charging target pixel electrodes corresponding with each of coordinate point positions in the position information respectively until reaching a target voltage matching each of the target pixel electrodes; based on the target voltage matching each of the target pixel electrodes, controlling discrete droplets in the display apparatus to move to the coordinate point positions corresponding with each of the target pixel electrodes respectively; and powering off each of the target pixel electrodes, obtaining the target content indicated by the discrete droplets and displaying it. In this way, the accurate presentation of the content displayed by the discrete droplets can be ensured.

A pattern electrode structure stacked between a base material and a dielectric layer of an electro-wetting device includes a center branch electrode extending in a first direction, and a plurality of sub-branch electrodes extending from the center branch electrode in an inclined direction relative to the first direction. According to the present disclosure, self-cleaning performance can be more efficiently exhibited even for small droplets.

A pattern electrode structure, which is stacked between a base material and a dielectric layer of an electro-wetting apparatus, includes a plurality of branch electrodes formed in a direction perpendicular to an arbitrary plane perpendicular to a plane formed by the pattern electrode structure to be spaced from each other at regular intervals, and a plurality of sub-branch electrodes formed to extend from the plurality of branch electrodes by as much as a predetermined length in an inclined direction, whereby, self-cleaning performance may be more efficiently exhibited even for small droplets.